Assessing the impact of the CPU power-saving modes on the task-parallel solution of sparse linear systems

José I. Aliaga; María Barreda; Manuel F. Dolz; Alberto F. Martín; Rafael Mayo; Enrique S. Quintana-Ortí

doi:10.1007/s10586-014-0402-z

Assessing the impact of the CPU power-saving modes on the task-parallel solution of sparse linear systems

José I. Aliaga
, María Barreda
, Manuel F. Dolz
, Alberto F. Martín
, Rafael Mayo
, Enrique S. Quintana-Ortí^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

11 Citations (Scopus)

Abstract

We investigate the benefits that an energy-aware implementation of the runtime in charge of the concurrent execution of ILUPACK—a sophisticated preconditioned iterative solver for sparse linear systems—produces on the time-power-energy balance of the application. Furthermore, to connect the experimental results with the theory, we propose several simple yet accurate power models that capture the variations of average power that result from the introduction of the energy-aware strategies as well as the impact of the P-states into ILUPACK’s runtime, at high accuracy, on two distinct platforms based on multicore technology from AMD and Intel.

Original language	English
Pages (from-to)	1335-1348
Number of pages	14
Journal	Cluster Computing
Volume	17
Issue number	4
DOIs	https://doi.org/10.1007/s10586-014-0402-z
Publication status	Published - 15 Nov 2014
Externally published	Yes

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title = "Assessing the impact of the CPU power-saving modes on the task-parallel solution of sparse linear systems",

abstract = "We investigate the benefits that an energy-aware implementation of the runtime in charge of the concurrent execution of ILUPACK—a sophisticated preconditioned iterative solver for sparse linear systems—produces on the time-power-energy balance of the application. Furthermore, to connect the experimental results with the theory, we propose several simple yet accurate power models that capture the variations of average power that result from the introduction of the energy-aware strategies as well as the impact of the P-states into ILUPACK{\textquoteright}s runtime, at high accuracy, on two distinct platforms based on multicore technology from AMD and Intel.",

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AU - Aliaga, José I.

AU - Barreda, María

AU - Dolz, Manuel F.

AU - Martín, Alberto F.

AU - Mayo, Rafael

AU - Quintana-Ortí, Enrique S.

PY - 2014/11/15

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N2 - We investigate the benefits that an energy-aware implementation of the runtime in charge of the concurrent execution of ILUPACK—a sophisticated preconditioned iterative solver for sparse linear systems—produces on the time-power-energy balance of the application. Furthermore, to connect the experimental results with the theory, we propose several simple yet accurate power models that capture the variations of average power that result from the introduction of the energy-aware strategies as well as the impact of the P-states into ILUPACK’s runtime, at high accuracy, on two distinct platforms based on multicore technology from AMD and Intel.

AB - We investigate the benefits that an energy-aware implementation of the runtime in charge of the concurrent execution of ILUPACK—a sophisticated preconditioned iterative solver for sparse linear systems—produces on the time-power-energy balance of the application. Furthermore, to connect the experimental results with the theory, we propose several simple yet accurate power models that capture the variations of average power that result from the introduction of the energy-aware strategies as well as the impact of the P-states into ILUPACK’s runtime, at high accuracy, on two distinct platforms based on multicore technology from AMD and Intel.

KW - CPU power-saving modes

KW - Energy-aware methods

KW - High performance computing

KW - ILUPACK

KW - Iterative solvers

KW - Sparse linear systems

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DO - 10.1007/s10586-014-0402-z

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SP - 1335

EP - 1348

JO - Cluster Computing

JF - Cluster Computing

IS - 4

ER -

Assessing the impact of the CPU power-saving modes on the task-parallel solution of sparse linear systems

Abstract

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